Demonstration of a high extinction ratio TiN-based TM-pass waveguide polarizer

IF 0.7 4区物理与天体物理 Q4 OPTICS

Optica Applicata Pub Date : 2022-01-01 DOI:10.37190/oa220409

Zhuan Zhao, G. Santi, A. Corso, M. Pelizzo

引用次数: 0

Abstract

A high extinction ratio transverse magnetic (TM)-pass plasmonic waveguide polarizer has been designed and optimized. This device exploits two parallel TiN strips embedded in a silicon dioxide cladding to cut off the transverse electric (TE) polarization state, which is either reflected or absorbed, while the TM mode can pass through the main silicon waveguide with significant low losses. Given a device of 5 µm length, an extinction ratio as high as 60.7 dB and an insertion loss of 2.23 dB were achieved at the target wavelength of 1.55 µm. To our knowledge, this extinction ratio is one of the highest values ever reported. In the wavelength of 1.45–1.59 µm, the proposed device provides an optical bandwidth of 140 nm for an extinction ratio more than 30 dB and an insertion loss less than 3 dB. This device is relatively simple and is easier to be fabricated than other architectures that are found in the literature.

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高消光比tin基tm通波导偏振器的演示

设计并优化了一种高消光比横向磁通等离子波导偏振器。该器件利用嵌入在二氧化硅包层中的两条平行TiN条来切断横向电(TE)偏振态，该偏振态要么被反射，要么被吸收，而TM模式可以通过主硅波导，损耗很低。对于长度为5µm的器件，在1.55µm的目标波长处，消光比高达60.7 dB，插入损耗为2.23 dB。据我们所知，这一灭绝比率是有史以来报道的最高值之一。在1.45-1.59µm波长范围内，该器件可提供140 nm的光带宽，消光比大于30 dB，插入损耗小于3 dB。该装置相对简单，比文献中发现的其他结构更容易制造。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Optica Applicata 物理-光学

CiteScore

1.00

自引率

16.70%

发文量

审稿时长

4 months

期刊介绍： Acoustooptics, atmospheric and ocean optics, atomic and molecular optics, coherence and statistical optics, biooptics, colorimetry, diffraction and gratings, ellipsometry and polarimetry, fiber optics and optical communication, Fourier optics, holography, integrated optics, lasers and their applications, light detectors, light and electron beams, light sources, liquid crystals, medical optics, metamaterials, microoptics, nonlinear optics, optical and electron microscopy, optical computing, optical design and fabrication, optical imaging, optical instrumentation, optical materials, optical measurements, optical modulation, optical properties of solids and thin films, optical sensing, optical systems and their elements, optical trapping, optometry, photoelasticity, photonic crystals, photonic crystal fibers, photonic devices, physical optics, quantum optics, slow and fast light, spectroscopy, storage and processing of optical information, ultrafast optics.